Data input (tutorial)
Normally, visone reads network data from GraphML files, which should never cause any problems. However, in some cases it is necessary to import data stemming from other sources that can, for instance, export adjacency matrices to comma-separated-value (CSV) tables. This tutorial guides you through the various possibilities to input data into visone.
- 1 The usual way: read GraphML
- 2 An overview about the other possibilities
- 3 The variants of comma-separated-value (CSV) files
- 4 Adjacency matrix files
- 5 Link list files
- 6 Adjacency list files
- 7 Importing node and link attributes
- 8 Other supported formats
- 9 If nothing else works: use the R console or KNIME connection
The usual way: read GraphML
GraphML is the usual file format for visone; it encodes the three types of information that are contained in visone networks: network structure, attributes, and graphical information and it is the only format that does so. To read network data from GraphML files use the file menu, click on open..., select files of type .graphml, and click on the ok button.
The other file types are only needed when you want to import data from other sources that cannot output GraphML.
An overview about the other possibilities
Apart from GraphML, visone can read network data from files that are exported by other network analysis software, including UCINET, Pajek, Siena, and some more. Opening these files is also done via the file menu by selecting the appropriate file type. More information about reading these file types is provided in the section about other supported formats.
A more basic option that should be feasible in most situations is to read network data from comma-separated-value (CSV) files. CSV files are plain-text files, for example looking like this
;A;B;C;D A;0;1;1;1 B;1;0;1;0 C;1;1;0;0 D;1;0;0;0
that can be created by spread sheet editors (such as MS Excel), statistical software, most network analysis software, and many more. However, reading data from CSV files is more error-prone since these files do not come with an unequivocal definition about how to interpret them (rather you have to tell the program how these files should be interpreted). Most of this tutorial is dedicated to the import of CSV files.
If nothing else works, you can make use of the visone R console that allows access to the R environment for statistical computing or you can read data via the KNIME connection that connects visone to a comprehensive data mining workflow tool. Both environments, R and KNIME, provide very general and configurable methods for data input and, in addition, enable you to preprocess and/or filter the data with relatively low effort. We provide more information about these possibilities in the section "if nothing else works".
Yet another possibility to create networks directly in visone is to enter them manually (which is only appropriate if the neworks are small and the data is not yet available in electronic format). This option is illustrated in the tutorial introducing the visual network editor.
The variants of comma-separated-value (CSV) files
A comma-separated-value file can be thought of as a plain-text file that encodes a table, i.e., a data array that has rows and columns - sometimes also referred to as a matrix. In a network context, there are different possibilities to encode information about nodes, links, or attribute information in such tables. The first three (adjacency matrices, link lists, and adjacency lists) provide information about nodes and links and can be opened via the file menu by selecting the appropriate file type. Attribute tables provide information about node or link attributes and can be opened via the attribute manager. What follows is a short characterization of these file types; more exhaustive explanation about how to read them is given in the following sections.
Adjacency matrix files. An adjacency matrix encodes for all pairs of nodes (indexing the rows and columns of the table) whether or not there is a link connecting these nodes. An example is shown in the following.
;A;B;C;D A;0;1;1;1 B;0;0;1;0 C;1;1;0;0 D;1;0;0;0
The first row and the first column are the labels of the nodes; the remaining part encodes whether there is a link from the node indexing the row to the node indexing the column. For instance, the character 1 in the row indexed by A and the column indexed by B indicates that there is a link going from A to B; the 0 in the row B and column A indicates that there is no link in the reverse direction.
Link list files. A link list contains as many rows as there are links in the network and (in its most basic form) a link list contains two columns where the entry in the first column is the identifier for the source node and the entry in the second column denotes the target node of the link. The following example
A;C C;B B;A A;D
defines four links: from node A to node C, from C to B, etc. Note that link lists use less space than adjacency matrices - especially if the network is very sparse (i.e., when the number of links divided by the number of node pairs is a small value close to zero).
Adjacency list files. An adjacency list has as many rows as there are nodes in the network. Each row may have a different length and the row associated with a node lists all neighbors of this node. For instance, in the following example
A;2;3;1 B;0;2 C;1;0 D;0
the labels at the beginning of each row are the node identifiers (these ids are optional);
A is the label of the node with index 0,
B is the label of the node with index 1, etc; the list
2;3;1 following the label
A defines that there are links from
A to the node with index 2 (labeled
C), to the node with index 3 (
D), and to the node with index 1 (
Attribute tables. An attribute table has one row that lists the attribute names (in the example below this is id;age;smokes followed by as many rows as there are nodes in the network.
id;age;smokes A;23;false B;28;true C;19;true D;27;false
One of the columns (id in the example above) lists the unique node identifiers (it is not necessarily the first row and not necessarily labeled id). The other columns list the attribute values of the attribute whose name is given in the respective column header. Attribute files are not read via the file menu but can only be added to an existing network via the attribute manager.
Note: visone does not allow to simultaneously input an adjacency matrix together with given attributes in one file. That is, a file like
;A;B;C;D;age;smokes A;0;1;1;1;23;false B;1;0;1;0;28;true C;1;1;0;0;19;true D;1;0;0;0;27;false
(having the interpretation that the first four columns specify an adjacency matrix and the last two columns define node attribute values) cannot be opened. Rather you have to split this into two separate files, one containing the adjacency matrix which can be opened via the file menu and the other containing the attribute table which can be opened via the attribute manager. (For instance, in MS Excel you could split the file by selecting columns, copy them, and past them into a new table.)
The next four sections explain the various options that have to be set when reading CSV files.
Adjacency matrix files
To open an adjacency matrix, use the file menu, click on open..., select files of type CSV files (.txt, .csv) in the file chooser, navigate to the file you want to open, and click on the ok button. Then the import options dialog opens (show below).
The semantics of the various options is explained in the following.
- data format is used to disinguish between adjacency matrix files and other types of CSV files (here choose adjacency matrix).
- network type can be one mode or two mode. In the adjacency matrix of a one mode network the rows and columns are indexed by the same set of nodes; for a two mode network (for instance, a network connecting authors to the articles they have written), the rows and columns are indexed by different sets of node (authors respectively articles in the example).
- link attribute type can be decimal or text. The entries of the adjacency matrix (which are either numbers or character strings) are saved in a link attribute of the newly opened network; this option defines the type of this attribute (decimal for numerical attributes and text for categorical).
- The check boxes row labels and header indicate whether the first column (respectively first row) lists the node identifiers (rather then entries of the adjacency matrix). If unchecked, then the node identifiers will be the numbers from to (when there are nodes in the network).
- The check box directed edges is used to choose between directed and undirected networks.
- The file format can be MS Excel, OpenOffice (default CSV output of these software programs, respectively), or user defined. If it is set to user defined you have to specify the following options.
- cell delimiter defines the character that separates one matrix cell from the next. In the examples above, the cell delimiter is the semicolon (;) but it can as well be a comma, colon, TAB, or SPACE character.
- textframe can be double quotes, quotes, or NONE. Textframes are necessary if the matrix-cell entries themselves contain the cell delimiter. (For instance, if the cell delimiter is SPACE and the row/column labels are "firstname lastname"; the quotes tell visone that the cell does not end after firstname.)
- The merge empty cells checkbox tells visone whether repeated cell delimiters should be treated as one. This option is for instance necessary when reading the Newcomb Fraternity data (of which an excerpt is shown below)
0 7 12 11 10 4 13 14 15 16 3 9 1 5 8 6 2 8 0 16 1 11 12 2 14 10 13 15 6 7 9 5 3 4 13 10 0 7 8 11 9 15 6 5 2 1 16 12 4 14 3 ...
where the cell delimiter (the SPACE character) is sometimes repeated to enhance (human) readability.
The bottom part of the dialog shows the table in the way that it will be interpreted with the current setting. This part allows you to recognize whether the options are set correctly.
When you have set the options, click on the ok button to open the file.
Link list files
To open a link list, use the file menu, click on open..., select files of type CSV files (.txt, .csv) in the file chooser, navigate to the file you want to open, and click on the ok button. Then the import options dialog opens (show below).
Many options have the same meaning as when reading adjacency matrices (explained above). The most crucial difference is that in the first row of the preview area you select two specific columns, one containing the source of the link (indicated by the label source in the very first row) and one containing the target of the link (indicated by target). The other columns contain link attributes that you might choose to import (if set to enabled) or ignore (if set to disabled).
In the example above (see the tutorial on Wikipedia edit networks to learn more about this data), the column with the header ActiveUser contains the link source and the column labeled Target contains the link target. The other columns (WordCount, InteractionType, etc) hold the values of various link attributes that are newly created if not already in the network. Note that the type of these attributes can be set to be text, integer, decimal, etc in the second row of the preview area.
If the links in a link list have associated time-information (encoding when the interaction happened) - or if the order in the file is meaningful und could be interpreted in the sense that interaction on the begining of the file happened earlier - you might consider opening them as event list files (this is illustrated in the tutorial on event networks).
Adjacency list files
To open an adjacency list, use the file menu, click on open..., select files of type adjacency list files (.txt, .csv) in the file chooser, navigate to the file you want to open, and click on the ok button. Then the import options dialog opens (show below).
- The header checkbox defines whether the first row is a header giving the numbers of nodes and links in the file (rather then the adjacency list of the first node).
- node labels indicates whether the first column list the node identifiers (if unchecked, then nodes are numbered consecutively and the 'th row list the neighbors of the 'th node).
- directed defines links are treated as directed or undirected.
The other options have the same meaning as when reading adjacency matrices (explained above).
To open an attribute table and add attribute values to the nodes or links of a network that is already opened in visone, use the attribute manager which can be started by clicking on the icon in visone's toolbar.
In the attribute manager, choose the node or link button in the top row, import & export on the left, operation import in the drop-down menu, and select the CSV file that contains the attributes you want to import
Before clicking on apply it is very important to correctly set the value in the join by drop-down menu. This should point to the name of the attribute that identifies the nodes (or links) and tells visone which column in the imported CSV file holds these identifiers. The identifying attribute must be identical to the header of the column that contains the identifiers (see below). The other columns contain the names and values of the other attributes. For instance, the node with id A gets a value of 23 for the age attribute and the value false for the smokes attribute. (When reading attribute tables you need column headers.)
id;age;smokes A;23;false B;28;true C;19;true D;27;false
Clicking on the apply button opens the import options which have the same meaning as when reading adjacency matrices (explained above).
Other supported formats
If nothing else works: use the R console or KNIME connection
visone offers the R console with which network data can be sent from visone to R and back. This ability to load data from R - together with R's data input and data processing capabilities - opens nearly unlimited possibilities to import data from yet other sources, as well as to import data that has to be cleaned, filtered, or preprocessed before turning it into a network.
The basic functioning of the visone to R interface is explained in the R tutorial. Tutorials about working with R are linked from the R website. A particular useful R package for data input is the foreign package for "reading and writing data stored by statistical packages such as Minitab, S, SAS, SPSS, Stata, Systat, ..., and for reading and writing dBase files."